/* ChibiOS/RT - Copyright (C) 2006,2007,2008,2009,2010 Giovanni Di Sirio. This file is part of ChibiOS/RT. ChibiOS/RT is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. ChibiOS/RT is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ /** * @file LPC214x/serial_lld.c * @brief LPC214x low level serial driver code. * * @addtogroup LPC214x_SERIAL * @{ */ #include "ch.h" #include "hal.h" #if CH_HAL_USE_SERIAL || defined(__DOXYGEN__) /*===========================================================================*/ /* Driver exported variables. */ /*===========================================================================*/ #if USE_LPC214x_UART0 || defined(__DOXYGEN__) /** @brief UART0 serial driver identifier.*/ SerialDriver SD1; #endif #if USE_LPC214x_UART1 || defined(__DOXYGEN__) /** @brief UART1 serial driver identifier.*/ SerialDriver SD2; #endif /*===========================================================================*/ /* Driver local variables. */ /*===========================================================================*/ /** @brief Driver default configuration.*/ static const SerialConfig default_config = { SERIAL_DEFAULT_BITRATE, LCR_WL8 | LCR_STOP1 | LCR_NOPARITY, FCR_TRIGGER0 }; /*===========================================================================*/ /* Driver local functions. */ /*===========================================================================*/ /** * @brief UART initialization. * * @param[in] sdp communication channel associated to the UART * @param[in] config the architecture-dependent serial driver configuration */ static void uart_init(SerialDriver *sdp, const SerialConfig *config) { UART *u = sdp->uart; uint32_t div = PCLK / (config->sc_speed << 4); u->UART_LCR = config->sc_lcr | LCR_DLAB; u->UART_DLL = div; u->UART_DLM = div >> 8; u->UART_LCR = config->sc_lcr; u->UART_FCR = FCR_ENABLE | FCR_RXRESET | FCR_TXRESET | config->sc_fcr; u->UART_ACR = 0; u->UART_FDR = 0x10; u->UART_TER = TER_ENABLE; u->UART_IER = IER_RBR | IER_STATUS; } /** * @brief UART de-initialization. * * @param[in] u pointer to an UART I/O block */ static void uart_deinit(UART *u) { u->UART_LCR = LCR_DLAB; u->UART_DLL = 1; u->UART_DLM = 0; u->UART_LCR = 0; u->UART_FDR = 0x10; u->UART_IER = 0; u->UART_FCR = FCR_RXRESET | FCR_TXRESET; u->UART_ACR = 0; u->UART_TER = TER_ENABLE; } /** * @brief Error handling routine. * * @param[in] sdp communication channel associated to the UART * @param[in] err UART LSR register value */ static void set_error(SerialDriver *sdp, IOREG32 err) { sdflags_t sts = 0; if (err & LSR_OVERRUN) sts |= SD_OVERRUN_ERROR; if (err & LSR_PARITY) sts |= SD_PARITY_ERROR; if (err & LSR_FRAMING) sts |= SD_FRAMING_ERROR; if (err & LSR_BREAK) sts |= SD_BREAK_DETECTED; chSysLockFromIsr(); sdAddFlagsI(sdp, sts); chSysUnlockFromIsr(); } #if defined(__GNU__) __attribute__((noinline)) #endif /** * @brief Common IRQ handler. * @note Tries hard to clear all the pending interrupt sources, we dont want * to go through the whole ISR and have another interrupt soon after. * * @param[in] u pointer to an UART I/O block * @param[in] sdp communication channel associated to the UART */ static void serve_interrupt(SerialDriver *sdp) { UART *u = sdp->uart; while (TRUE) { switch (u->UART_IIR & IIR_SRC_MASK) { case IIR_SRC_NONE: return; case IIR_SRC_ERROR: set_error(sdp, u->UART_LSR); break; case IIR_SRC_TIMEOUT: case IIR_SRC_RX: chSysLockFromIsr(); if (chIQIsEmptyI(&sdp->iqueue)) chEvtBroadcastI(&sdp->ievent); chSysUnlockFromIsr(); while (u->UART_LSR & LSR_RBR_FULL) { chSysLockFromIsr(); if (chIQPutI(&sdp->iqueue, u->UART_RBR) < Q_OK) sdAddFlagsI(sdp, SD_OVERRUN_ERROR); chSysUnlockFromIsr(); } break; case IIR_SRC_TX: { int i = LPC214x_UART_FIFO_PRELOAD; do { msg_t b; chSysLockFromIsr(); b = chOQGetI(&sdp->oqueue); chSysUnlockFromIsr(); if (b < Q_OK) { u->UART_IER &= ~IER_THRE; chSysLockFromIsr(); chEvtBroadcastI(&sdp->oevent); chSysUnlockFromIsr(); break; } u->UART_THR = b; } while (--i); } break; default: (void) u->UART_THR; (void) u->UART_RBR; } } } /** * @brief Attempts a TX FIFO preload. */ static void preload(SerialDriver *sdp) { UART *u = sdp->uart; if (u->UART_LSR & LSR_THRE) { int i = LPC214x_UART_FIFO_PRELOAD; do { msg_t b = chOQGetI(&sdp->oqueue); if (b < Q_OK) { chEvtBroadcastI(&sdp->oevent); return; } u->UART_THR = b; } while (--i); } u->UART_IER |= IER_THRE; } /** * @brief Driver SD1 output notification. */ #if USE_LPC214x_UART0 || defined(__DOXYGEN__) static void notify1(void) { preload(&SD1); } #endif /** * @brief Driver SD2 output notification. */ #if USE_LPC214x_UART1 || defined(__DOXYGEN__) static void notify2(void) { preload(&SD2); } #endif /*===========================================================================*/ /* Driver interrupt handlers. */ /*===========================================================================*/ /** * @brief UART0 IRQ handler. */ #if USE_LPC214x_UART0 || defined(__DOXYGEN__) CH_IRQ_HANDLER(UART0IrqHandler) { CH_IRQ_PROLOGUE(); serve_interrupt(&SD1); VICVectAddr = 0; CH_IRQ_EPILOGUE(); } #endif /** * @brief UART1 IRQ handler. */ #if USE_LPC214x_UART1 || defined(__DOXYGEN__) CH_IRQ_HANDLER(UART1IrqHandler) { CH_IRQ_PROLOGUE(); serve_interrupt(&SD2); VICVectAddr = 0; CH_IRQ_EPILOGUE(); } #endif /*===========================================================================*/ /* Driver exported functions. */ /*===========================================================================*/ /** * @brief Low level serial driver initialization. */ void sd_lld_init(void) { #if USE_LPC214x_UART0 sdObjectInit(&SD1, NULL, notify1); SD1.uart = U0Base; SetVICVector(UART0IrqHandler, LPC214x_UART0_PRIORITY, SOURCE_UART0); #endif #if USE_LPC214x_UART1 sdObjectInit(&SD2, NULL, notify2); SD2.uart = U1Base; SetVICVector(UART1IrqHandler, LPC214x_UART1_PRIORITY, SOURCE_UART1); #endif } /** * @brief Low level serial driver configuration and (re)start. * * @param[in] sdp pointer to a @p SerialDriver object * @param[in] config the architecture-dependent serial driver configuration. * If this parameter is set to @p NULL then a default * configuration is used. */ void sd_lld_start(SerialDriver *sdp, const SerialConfig *config) { if (config == NULL) config = &default_config; if (sdp->state == SD_STOP) { #if USE_LPC214x_UART0 if (&SD1 == sdp) { PCONP = (PCONP & PCALL) | PCUART0; VICIntEnable = INTMASK(SOURCE_UART0); } #endif #if USE_LPC214x_UART1 if (&SD2 == sdp) { PCONP = (PCONP & PCALL) | PCUART1; VICIntEnable = INTMASK(SOURCE_UART1); } #endif } uart_init(sdp, config); } /** * @brief Low level serial driver stop. * @details De-initializes the UART, stops the associated clock, resets the * interrupt vector. * * @param[in] sdp pointer to a @p SerialDriver object */ void sd_lld_stop(SerialDriver *sdp) { if (sdp->state == SD_READY) { uart_deinit(sdp->uart); #if USE_LPC214x_UART0 if (&SD1 == sdp) { PCONP = (PCONP & PCALL) & ~PCUART0; VICIntEnClear = INTMASK(SOURCE_UART0); return; } #endif #if USE_LPC214x_UART1 if (&SD2 == sdp) { PCONP = (PCONP & PCALL) & ~PCUART1; VICIntEnClear = INTMASK(SOURCE_UART1); return; } #endif } } #endif /* CH_HAL_USE_SERIAL */ /** @} */